Clinical UM Guideline |
Subject: Serum Iron Testing | |
Guideline #: CG-LAB-21 | Publish Date: 04/10/2024 |
Status: Reviewed | Last Review Date: 02/15/2024 |
Description |
This document addresses laboratory testing for iron levels. Iron studies can include serum testing of ferritin, iron, and either iron binding capacity or transferrin. These tests are used in the differential diagnosis of iron deficiency, anemia, and iron overload.
Clinical Indications |
Medically Necessary:
Serum iron testing is considered medically necessary for any of the following indications:
Not Medically Necessary:
Serum iron testing is considered not medically necessary when the above criteria are not met, and for all other indications, including but not limited to the following:
Concurrent assessment of transferrin and TIBC is considered not medically necessary for any indication.
Coding |
The following codes for treatments and procedures applicable to this guideline are included below for informational purposes. Inclusion or exclusion of a procedure, diagnosis or device code(s) does not constitute or imply member coverage or provider reimbursement policy. Please refer to the member's contract benefits in effect at the time of service to determine coverage or non-coverage of these services as it applies to an individual member.
When services may be Medically Necessary when criteria are met:
CPT |
| |
82728 | Ferritin | |
83540 | Iron | |
83550 | Iron binding capacity | |
84466 | Transferrin | |
|
| |
ICD-10 Diagnosis |
| |
A01.00-A02.9 | Typhoid fever, other Salmonella infections | |
A04.0-A04.9 | Other bacterial intestinal infections | |
A06.0-A09 | Amebiasis, other protozoal, viral and other/unspecified intestinal diseases/infections | |
A15.0 | Tuberculosis of lung | |
A18.01-A18.89 | Tuberculosis of other organs | |
B15.0-B19.9 | Viral hepatitis | |
B20 | Human Immunodeficiency virus (HIV) disease | |
B25.1 | Cytomegalovirus hepatitis | |
B52.0 | Plasmodium malariae malaria with nephropathy | |
C00.0-C96.9 | Malignant neoplasms | |
D00.00-D09.9 | In situ neoplasms | |
D10.0-D36.9 | Benign neoplasms, except benign neuroendocrine tumors | |
D37.01-D48.9 | Neoplasms of uncertain behavior, polycythemia vera and myelodysplastic syndrome | |
D49.0-D49.9 | Neoplasms of unspecified behavior | |
D50.0-D53.9 | Nutritional anemias | |
D56.0-D57.819 | Thalassemia, sickle-cell disorders | |
D62-D64.9 | Acute posthemorrhagic anemia, anemia in diseases classified elsewhere, other anemia | |
D65-D69.9 | Coagulation defects, purpura and other hemorrhagic conditions | |
D75.838-D75.839 | Thrombocytosis | |
E08.00-E13.9 | Diabetes mellitus | |
E23.0-E23.1 | Hypopituitarism | |
E23.6 | Other disorders of pituitary gland | |
E24.1 | Nelson's syndrome | |
E28.310-E28.39 | Primary ovarian failure | |
E29.1 | Testicular hypofunction | |
E40-E46 | Malnutrition | |
E61.1 | Iron deficiency | |
E64.0 | Sequelae of protein-calorie malnutrition | |
E75.26 | Sulfatase deficiency | |
E79.0 | Hyperuricemia without signs of inflammatory arthritis and tophaceous disease | |
E80.0-E80.29 | Porphyria | |
E83.10-E83.19 | Disorders of iron metabolism | |
E88.02 | Plasminogen deficiency | |
E89.3 | Postprocedural hypopituitarism | |
F45.8 | Other somatoform disorders | |
F50.00-F50.9 | Eating disorders | |
F98.21-F98.29 | Other feeding disorders of infancy and childhood | |
F98.3 | Pica of infancy and childhood | |
I12.0 | Hypertensive chronic kidney disease with stage 5 chronic kidney disease or end stage renal disease | |
I13.11 | Hypertensive heart and chronic kidney disease without heart failure, with stage 5 chronic kidney disease, or end stage renal disease | |
I13.2 | Hypertensive heart and chronic kidney disease with heart failure and with stage 5 chronic kidney disease, or end stage renal disease | |
I27.83 | Eisenmenger's syndrome | |
I42.0-I43 | Cardiomyopathy, cardiomyopathy in diseases classified elsewhere | |
I44.0-I49.9 | Atrioventricular and left bundle-branch block, other conduction disorders, cardiac arrest, paroxysmal tachycardia, atrial fibrillation, other cardiac arrhythmias | |
I50.1-I50.9 | Heart failure | |
K22.6 | Gastro-esophageal laceration-hemorrhage syndrome | |
K22.81-K22.89 | Other specified diseases of esophagus | |
K25.0-K28.9 | Gastric, duodenal, peptic, gastrojejunal ulcer | |
K29.00-K31.9 | Gastritis and duodenitis, functional dyspepsia, other diseases of stomach and duodenum | |
K50.00-K52.839 | Noninfective enteritis and colitis | |
K55.011-K55.33 | Other diseases of intestines | |
K56.699 | Other intestinal obstruction unspecified as to partial versus complete obstruction | |
K57.00-K57.93 | Diverticular disease of intestine | |
K62.5 | Hemorrhage of anus and rectum | |
K63.5 | Polyp of colon | |
K63.81 | Dieulafoy lesion of intestine | |
K70.0-K77 | Diseases of the liver | |
K90.0-K90.9 | Intestinal malabsorption | |
K91.2 | Postsurgical malabsorption, not elsewhere classified | |
K92.0-K92.2 | Hematemesis, melana, gastrointestinal hemorrhage, unspecified | |
K94.20-K94.29 | Gastrostomy complications | |
L28.0-L28.2 | Lichen simplex chronicus and prurigo | |
L29.0-L29.9 | Pruritis | |
L57.3 | Poikiloderma of Civatte | |
L63.0-L66.9 | Alopecia, other nonscarring hair loss | |
L80 | Vitiligo | |
L81.0-L81.9 | Other disorders of pigmentation | |
L98.1 | Factitial dermatitis | |
M07.60-M07.69 | Enteropathic arthropathies | |
M12.80-M12.9 | Other specific arthropathies, not elsewhere classified | |
M13.0-M13.179 | Other arthritis | |
M14.80 | Arthropathies in other specified diseases classified elsewhere, unspecific site | |
M1A.10X0-M1A.19X1 | Lead-induced chronic gout | |
M25.50-M25.59 | Pain in joint | |
M79.641-M79.646 | Pain in hand and fingers | |
M84.750A-M84.759S | Nontraumatic fracture, not elsewhere classified | |
M97.01XA-M97.9XXS | Periprosthetic fracture around internal prosthetic joint | |
N02.0-N02.B9 | Recurrent and persistent hematuria | |
N04.0-N04.A | Nephrotic syndrome | |
N08 | Glomerular disorders in diseases classified elsewhere | |
N18.1-N18.9 | Chronic kidney disease | |
N19 | Unspecified kidney failure | |
N50.0 | Atrophy of testis | |
N89.7 | Hematocolpos | |
N91.0-N93.9 | Absent/scanty/rare menstruation, excessive/frequent/irregular menstruation, other abnormal uterine and vaginal bleeding | |
N95.0 | Postmenopausal bleeding | |
N99.116 | Postprocedural urethral stricture, male, overlapping sites | |
O09.A0-O09.A3 | Supervision of pregnancy with history of molar pregnancy | |
O11.4-O11.5 | Pre-existing hypertension with pre-eclampsia, complicating childbirth or puerperium | |
O90.81 | Anemia of the puerperium | |
O99.011-O99.03 | Anemia complicating pregnancy, childbirth and the puerperium | |
O99.891-O99.893 | Other specified diseases and conditions complicating pregnancy, childbirth and the puerperium | |
P50.0-P57.9 | Hemorrhagic disorders of newborn, hemolytic disease of newborn | |
Q85.00-Q85.09 | Neurofibromatosis (nonmalignant) | |
R00.1 | Bradycardia, unspecified | |
R11.10-R11.2 | Vomiting, nausea with vomiting | |
R63.8 | Other symptoms and signs concerning food and fluid intake | |
R64 | Cachexia | |
R71.0-R71.8 | Abnormality of red blood cells | |
R74.01-R74.9 | Nonspecific elevation of levels of transaminase and lactic acid dehydrogenase [LDH] | |
R78.71-R78.79 | Finding of abnormal level of heavy metals in blood | |
R78.89 | Finding of other specified substances, not normally found in blood | |
R79.0-R79.9 | Other abnormal findings of blood chemistry | |
T40.411A-T40.415S | Poisoning by, adverse effect of fentanyl or fentanyl analogs | |
T40.421A-T40.425S | Poisoning by, adverse effect of tramadol | |
T40.491A-T40.495S | Poisoning by, adverse effect of other synthetic narcotics | |
T43.641A-T43.644S | Poisoning by ecstasy | |
T45.4X1A-T45.4X4S | Poisoning by iron and its compounds | |
T50.911A-T50.915S | Poisoning by, adverse effect of multiple unspecified drugs, medicaments and biological substances | |
T56.0X1A-T56.0X4S | Toxic effect of lead and its compounds | |
T80.89XA | Other complications following infusion, transfusion and therapeutic injection, initial encounter | |
T80.910A-T80.919S | Hemolytic transfusion reaction, unspecified incompatibility | |
T80.92XA | Unspecified transfusion reaction, initial encounter | |
T86.00-T86.09 | Complications of bone marrow transplant | |
Z21 | Asymptomatic human immunodeficiency virus [HIV] infection status | |
Z31.7 | Encounter for procreative management and counseling for gestational carrier | |
Z49.31-Z49.32 | Encounter for adequacy testing for dialysis | |
Z83.430-Z83.438 | Family history of other disorder of lipoprotein metabolism and other lipidemias | |
Z84.82 | Family history of sudden infant death syndrome | |
Z86.2 | Personal history of diseases of the blood and blood-forming organs and certain disorders involving the immune mechanism | |
Z86.39 | Personal history of other endocrine, nutritional and metabolic disease | |
Z95.0-Z95.9 | Presence of cardiac and vascular implants and grafts | |
Z96.60 | Presence of unspecified orthopedic joint implant | |
Z98.870-Z98.871 | Personal history of in utero procedure | |
Z98.890-Z98.891 | Other specified postprocedural states |
When services are Not Medically Necessary:
For the procedure codes listed above for all other diagnoses not listed.
Discussion/General Information |
Reference standard indices of iron deficiency and iron overload, which include bone marrow iron content and liver iron content assessments, are generally invasive, unpleasant, and have the potential for associated risks. Alternatively, serum iron testing has been proposed as an alternative strategy for screening, diagnosis, and monitoring of conditions associated with iron deficiency and iron overload.
Iron deficiency
The most common disorder of iron homeostasis is iron deficiency. Iron deficiency represents approximately 40% of cases of anemia in the United States (United States Preventive Services Task Force [USPSTF], 2015b). Iron deficiency can occur when there is an increased demand for iron (such as during periods of rapid growth), when there is decreased iron intake and absorption, or blood loss. In adults in resource-rich countries, dietary intake is frequently adequate. Inadequate supplies of iron can lead to a disruption in circulating hemoglobin known as iron deficiency anemia. Iron deficiency anemias can be classified as absolute or functional iron deficiencies. Absolute iron deficiency anemia results when the iron stores become so low that hemoglobin synthesis is impaired causing anemia. In functional iron deficiency, the supply of iron for erythropoiesis is inadequate despite apparently normal iron stores (Snook, 2021). In the United States during 1999 and 2000, the estimated prevalence of iron deficiency ranged from 2% to 16% with higher prevalence in children aged 1 to 2 years and in individuals subject to uterine blood loss between ages 12 to 49 years (Centers for Disease Control [CDC], 2002). Iron deficiency anemia was most common in individuals subject to uterine blood loss. Prevalence for these individuals was 4% between the ages of 20 to 49 years and 3% for those aged 50 to 69 years (CDC, 2002). Treatment involves an assessment to address underlying causes and may include diet modification, oral or intravenous iron supplementation, or transfusion of red blood cells.
Iron deficiency anemia is more common in certain groups than the general population. Increased iron demands due to blood loss during menstruation, pregnancy, and in the postpartum period as well as tissue growth during pregnancy places individuals who may become pregnant at increased risk of iron deficiency anemia (CDC, 1998). General symptoms may include pallor, weakness, dyspnea, dizziness, rapid heartbeat, headache, dry rough skin, damaged hair, and restless leg syndrome (American Society of Hematology, 2021; Aul, 1998). People with mild or moderate iron deficiency anemia may not have any signs or symptoms. Severe iron deficiency anemia may cause fatigue or tiredness, shortness of breath, or chest pain. The possibility of iron deficiency is typically explored in individuals when the cause of anemia is unclear. Abnormal blood count values may require investigation. A decreased mean corpuscular volume (MCV) is commonly associated with iron deficiency or thalassemic syndromes. A decreased hemoglobin and hematocrit when the MCV is low or normal could indicate anemia of chronic disease or inflammation, but may be seen in hypothyroidism, chronic kidney disease, iron deficiency, or vitamin B12 and folate deficiencies. An increased red cell distribution width (RDW) and a low or normal MCV could also be associated with iron deficiency anemia, blood transfusion, and vitamin B12 or folate deficiency (Society for the Advancement of Patient Blood Management, 2020). In individuals with folate and vitamin B12 deficiencies, it may be appropriate to evaluate iron status as these conditions may cause macrocytosis that masks the microcytosis caused by iron deficiency (Bilic, 2004; Hannibal, 2016).
Other situations that may require further investigation include chronic blood loss; pregnancy; individuals with atypical symptoms of malnutrition or abnormal appetite such as pica; gastrointestinal syndromes of malabsorption; anemia associated with chronic diseases such as heart failure, chronic inflammatory disorders, and in individuals with chronic kidney disease (CKD) who have anemia, or are receiving hemodialysis or an erythropoiesis-stimulating agent (ESA). Anemia of chronic disease can occur in individuals with acute or chronic immune activation. In states of increased inflammation, cytokines and cells of the reticuloendothelial system induce changes in iron homeostasis, the proliferation of erythroid progenitor cells, the production of erythropoietin, and the life span of red cells (Weiss, 2005).
Bone marrow iron content is considered the gold standard measurement for the diagnosis of iron deficiency, but is infrequently utilized and not recommended for routine testing. Serum iron testing can include an assessment of the following: iron, total iron binding capacity (TIBC), transferrin, and ferritin. The serum iron test measures circulating iron, most of which is bound to the transport protein transferrin. Serum iron is low in iron deficiency as well as in anemia of chronic disease. Serum iron can also fluctuate with iron-containing supplements and dietary intake as well as normal diurnal variation. By itself, low serum iron is not diagnostic of any condition and must be evaluated in consideration of other tests such as transferrin and ferritin (Auerbach, 2016). In iron deficiency, iron is reduced and TIBC is increased. Transferrin proteins facilitate iron uptake and transport to red blood cell precursors in the bone marrow. Levels of transferrin are elevated in iron deficiency anemia. It is not ordinarily necessary to measure both transferrin and TIBC at the same time because TIBC is an indirect measure of transferrin (Auerbach, 2016). The serum iron and the TIBC are used to calculate percent transferrin saturation (TSAT). Ferritin is a blood protein that contains iron. A low ferritin level may indicate reduced iron stores and absolute iron deficiency (Aapro, 2018, Cullis, 2018). A very low ferritin level is diagnostic of iron deficiency when present, but ferritin levels may be elevated or falsely normal in individuals with comorbidities and cannot be used independently to eliminate the possibility of iron deficiency. The TSAT is a key test in the further investigation of an unexpectedly raised serum ferritin (Cullis, 2018). Although investigating bone marrow iron stores is still considered the standard index, circulating ferritin levels are used for distinguishing between absolute and functional iron deficiency in clinical practice (Aapro, 2018).
Garcia-Casal and colleagues (2021) published a Cochrane Review evaluating the diagnostic accuracy of ferritin concentrations for detecting iron deficiency and the risk of iron overload in primary and secondary iron-loading syndromes. The review of evidence related to iron deficiency included 72 studies involving 6059 individuals. In the general, apparently healthy adult population, 3 studies reported sensitivities of 63% to 100% at the optimum cutoff for ferritin, with corresponding specificities of 92% to 98% with cutoff variations between studies. One study in healthy children reported a sensitivity of 74% and specificity of 77% and one in pregnant individuals reported a sensitivity of 88% with a specificity of 100%. However, confidence in the estimates is low due to the sparse, heterogenous data, and potential for bias. Among non-healthy adults using a fixed threshold of 30 µg/L, the pooled estimate for sensitivity was 79% (95% confidence interval [CI], 58% to 91%) and specificity was 98% (95% CI, 91% to 100%). The estimated odds ratio of 140 indicates it is a relatively highly informative test. Blood ferritin concentration appears to be reasonably sensitive and a very specific test for iron deficiency in people presenting for medical care, but the reviewers reported that the findings are based on evidence of low-certainty.
The British Society of Gastroenterology (BSG) published guidelines for the management of iron deficiency anemia in adults (Snook, 2021). Iron deficiency anemia can be caused by a range of gastrointestinal pathologies including cancer. The BSG recommends investigating gastrointestinal causes on an urgent basis in individuals with a new diagnosis of IDA without obvious explanation (evidence quality – high, consensus – 85%, statement strength – strong). The recommendations include the following statements:
The etiology of iron deficiency anemia could be the result of inadequate intake, poor gastrointestinal absorption, or gastrointestinal blood loss. In their guidelines on the gastrointestinal evaluation of iron deficiency anemia, the American Gastroenterological Association (AGA; Ko, 2020) recommends using a cutoff of 45 ng/mL over 15 ng/mL when using ferritin to diagnose iron deficiency, a strong recommendation based on high quality evidence. The AGA also comments that in individuals with inflammatory conditions or CKD, other laboratory tests such as C-reactive protein, TSAT, or soluble transferrin saturation, may be needed in conjunction with ferritin to diagnose iron deficiency anemia.
The American College of Obstetricians and Gynecologists (ACOG; 2021) guidelines for anemia in pregnancy recommend that all pregnant individuals should be screened for anemia with a CBC in the first trimester and again at 24 0/7 to 28 6/7 weeks of gestation. Those who meet criteria for anemia should be evaluated to determine the cause. The recommendations are based on consensus and expert opinion (Level C). The initial evaluation of pregnant individuals with mild to moderate anemia may include serum iron and ferritin levels. Iron deficiency anemia is defined by abnormal iron test values along with low hemoglobin or hematocrit levels. In individuals “without evidence of causes of anemia other than iron deficiency, it may be reasonable to empirically initiate iron therapy without first obtaining iron test results” (ACOG, 2021).
The World Health Organization (WHO; 2020) created guidelines addressing the use of indicators for assessing a population’s iron status and application of the use of ferritin concentration for monitoring and evaluating iron interventions. The guidance included the following recommendations related to the scope of this document:
In 2019, guidelines from the British Society of Haemotology issued the following recommendations for individuals who are pregnant:
The American Academy of Pediatrics (AAP; Hagan, 2017) issued guidelines that include recommendations on iron supplementation and screening for anemia. Their recommendations include universal screening for anemia in infants at age 12 months. For children at other ages, selective screening for anemia based on an assessment of risk during routine health examinations is recommended. Starting in adolescence, the AAP recommends screening all nonpregnant individuals who are subject to uterine blood loss for anemia every 5 to 10 years, throughout the years they have the potential to become pregnant, during routine health examinations. They also recommend annual screening for anemia in individuals subject to uterine blood loss with other known risk factors for iron deficiency that include extensive menstrual or other blood loss, low iron intake, or a previous diagnosis of iron deficiency anemia. Screening includes an assessment of hemoglobin. Specific testing for serum iron concentrations is not addressed in the guidelines. They include the following statement:
Screening for anemia has limited accuracy for iron deficiency. Treatment for iron deficiency anemia shows improvement in iron deficiency but not necessarily in developmental outcomes. Evidence suggests some harm caused by increased incidence of iron poisoning when iron-containing medications are kept in the home. No high-quality studies were found regarding screening adolescents for anemia.
Because iron deficiency is associated with many and sometimes subtle detrimental effects, the AAP recommends iron supplementation or fortification in infants. They also recommend that all infants at age 12 months be screened for anemia by determining hemoglobin concentration.
The United States Preventive Services Task Force (USPSTF) has issued separate guidance addressing iron deficiency anemia in young children (ages 6 to 24 months) and individuals who are pregnant (2015a; 2015b). In both groups, the USPSTF determined that evidence is insufficient to assess the balance of benefits and harms of screening for iron deficiency anemia with a Grade I recommendation. The guidelines included the following statement regarding individuals who are pregnant:
The primary screening test for anemia is to measure serum hemoglobin or hematocrit levels. However, given the hemodilution and physiologic anemia that normally occurs during pregnancy, using hemoglobin or hematocrit measurement alone to determine iron deficiency status can be imprecise, and its sensitivity and specificity for detecting iron deficiency anemia in pregnant women are unknown. Serum ferritin, which is often used to measure iron status, may have limited use during pregnancy because its concentration often decreases in late pregnancy despite adequate iron stores in the bone marrow. Also, serum ferritin is an acute phase reactant, which means its levels increase during periods of inflammation.
The CDC (1998) has developed guidelines for iron deficiency screening to detect deficiency at earlier stages and prevent serious complications of iron deficiency anemia in at-risk populations. According to the guidelines, secondary prevention for iron deficiency involves screening for, diagnosing, and treating iron-deficiency anemia. The CDC indicates that the cost, feasibility, and variability of measurements other than hemoglobin and hematocrit currently preclude their use for screening. Screening recommendations for infants ages 0 to 12 months and preschool children ages 1 to 5 years include the following:
Secondary Prevention Universal Screening
Selective Screening
The CDC (1998) recommends the following for diagnosis and treatment for infants and preschool aged children:
Among persons 5 to less than 12 years of age and individuals age 12 to less than 18 years who are not subject to uterine blood loss, the CDC recommends that “only those who have a history of iron-deficiency anemia, special health-care needs, or low iron intake should be screened for anemia” (CDC, 1998). Among individuals subject to uterine blood loss age 12 and older the CDC recommends the following:
Secondary Prevention Screening
Diagnosis and Treatment
For individuals who are pregnant and postpartum the CDC recommends:
Secondary Prevention Screening
Diagnosis and Treatment
Postpartum Women
Women at risk for anemia at 4-6 weeks postpartum should be screened for anemia by using a Hb concentration or Hct test…Risk factors include anemia continued through the third trimester, excessive blood loss during delivery, and a multiple birth. Treatment and follow-up for iron deficiency anemia in postpartum women are the same as for nonpregnant women.
For individuals who are not subject to uterine blood loss, including those who have experienced menopause, age greater than or equal to 18 years, the CDC states the following:
No routine screening for iron deficiency is recommended for men or postmenopausal women. Iron deficiency or anemia detected during routine medical examinations should be fully evaluated for its cause.
The Institute of Medicine (IOM; Earl, 1993) published guidance on the prevention, detection, and management of iron deficiency anemia among children and individuals that may become pregnant. The IOM recommends measuring hemoglobin and hematocrit levels to screen for anemia and suspected iron deficiency. However, they warn that this method may fail to recognize mild degrees of iron deficiency due to the overlap in values between normal and iron deficient individuals. Screening of infants who are breastfed or not receiving iron-fortified formula should occur at age 9 months or no later than age 3 months in preterm infants. If there is an infection or there has been an infection within the 2 weeks prior to screening, it should be delayed. Routine screening is not recommended for children over age 24 months, in the absence of anemia during a prior screening. Children at mid-youth may need to be screened in the presence of risk factors for iron deficiency anemia which may include abuse and resource limited conditions. The guidelines recommend that all individuals who may become pregnant should be screened for anemia between 15 and 25 years of age and every 5 to 10 years if there are no risk factors for anemia. More frequent screening is recommended for individuals with risk factors that include high parity, frequent blood donation, high menstrual blood loss, previous diagnosis of iron deficiency anemia, and resource-limited conditions. For individuals who are pregnant, the IOM recommends screening for anemia at the first prenatal visit and at the second-trimester visit by evaluating hemoglobin and ferritin concentrations.
Medical society guidelines make a distinction between evaluating individuals suspected to have iron deficiency anemia, evaluating asymptomatic individuals considered to be at increased risk, and individuals who are asymptomatic and not at increased risk of iron deficiency anemia. Universal screening of asymptomatic individuals who are not at risk of iron deficiency anemia is not recommended. Recommendations for initial screening typically include an evaluation of hemoglobin and hematocrit with a subsequent assessment of iron studies except in cases of known higher risk or suspicion of iron deficiency.
Iron Deficiency Anemia in Chronic Diseases
The cause of iron deficiency in chronic diseases can be multifactorial. Contributing factors may include malabsorption, malnutrition, GI blood loss, and the presence of a chronic inflammatory state. Impaired erythropoietic activity and disturbed iron homeostasis can be consequences of increased release of inflammatory cytokines due to chronic conditions such as underlying cancer or toxicity of cancer therapy, congestive heart failure, and CKD (Aapro, 2018; Snook, 2021).
Iron deficiency and anemia are considered common in individuals with heart failure. The European Society of Cardiology recommends that all individuals with heart failure are regularly screened for anemia and iron deficiency with a full blood count, serum ferritin concentration, and TSAT (McDonagh, 2021).
Anemia and iron deficiency can be common complications in individuals with solid tumors or hematologic malignancies, particularly those treated with chemotherapeutic agents. Iron replacement may be used to improve hemoglobin response and reduce red blood cell transfusions in individuals with chemotherapy associated anemia receiving ESA with or without iron deficiency. Baseline and periodic monitoring of iron, TIBC, transferrin saturation, or ferritin levels is recommended by the European Society of Medical Oncology and American Society of Oncology/American Society of Hematology (Aapro, 2018; Bohlius, 2019)
Among individuals with CKD, functional iron deficiency is related in part to the administration of ESA or anemia of chronic disease. Assessment of iron status is performed to determine if iron deficiency is causing or contributing to anemia, guide the use of iron therapy to achieve or maintain target hemoglobin levels, and avoid complications associated with iron overload. Measurement of serum iron, TIBC, ferritin, and TSAT are commonly used to assess iron status in this population.
The Renal Association (Mikhail, 2017) published clinical practice guidelines on anemia of CKD. The guidance indicates that initial laboratory evaluation for anemia should include tests to determine iron status (Grade 1B). These tests include percentage of hypochromic red blood cells (CHr), but only if processing of blood sample is possible within 6 hours, reticulocyte hemoglobin count (Ret-Hb), or equivalent tests. If testing for CHr or Ret-Hb is not feasible or the person has thalassemia or thalassemia trait, it is preferable to test ferritin and TSAT together because the combination provides an important insight into erythropoiesis, iron storage, and iron availability to bone marrow. Serum ferritin is considered the only available blood marker to assess iron stores and should also be obtained at the initial evaluation. It is recommended that iron status is monitored every 1 to 3 months in individuals receiving intravenous iron therapy to avoid toxicity (Grade 2B).
Clinical practice guidelines for anemia in individuals with CKD were published by the Kidney Disease: Improving Global Outcomes (KDIGO) Anemia Work Group (2012). The guidelines indicate that individuals with CKD and anemia should have a complete blood count, absolute reticulocyte count, serum ferritin, TSAT, vitamin B12, and folate levels measured at the initial evaluation of anemia. The recommendation was supported by a review from the National Kidney Foundation – Kidney Disease Outcomes Quality Initiative (Kliger, 2013). Ongoing assessment of hemoglobin, TSAT, and ferritin is considered necessary to monitor response to therapy. Evaluation of iron status, TSAT and ferritin, is recommended at least every 3 months during ESA therapy and for decision making regarding iron therapy. Testing iron status more frequently is recommended with ESA dose modifications, to monitor response to intravenously delivered iron therapy, when there is blood loss, and in other circumstances where iron stores may become depleted. These recommendations are not graded and based on limited evidence with few RCTs.
Guidelines from the International Society of Nephrology (Madore, 2008) recommend assessing iron status as part of the initial evaluation of anemia in all individuals with CKD. Frequency of iron testing is adapted to the individual’s condition. In individuals who require iron or ESA therapy, measurement of serum ferritin and TSAT every 1 to 3 months is considered reasonable. The frequency of follow-up evaluation is dependent an individual’s clinical status, hemoglobin response to iron supplementation, the ESA dose, and the results of recent iron studies. Evaluation would occur less frequently in stable individuals with mild anemia who are not receiving iron supplementation or ESA therapy, or more frequently during acute management.
Iron Overload
An excess of iron, iron overload, is a potentially serious problem with nonspecific and often gradual symptom development. Left untreated, individuals are at risk of life-threatening organ toxicity. Increased iron levels can be caused by red blood cell transfusions, excesses in iron supplementation, increases in iron absorption due hereditary hemochromatosis, ineffective erythropoiesis such as occurs in thalassemia, sickle cell anemia, and liver disease. Chronic alcohol consumption has also been associated with increased hepatic iron stores from increased intestinal iron absorption (Costa Matos, 2013). Iron overload syndromes are divided into three groups: inherited causes, various causes of secondary iron overload, and a small miscellaneous group. Typical findings in individuals with suspected iron overload may include a family history of hereditary hemochromatosis, multiple red blood cell transfusions, and unexplained organ damage (such as liver or heart damage) with its associated symptoms. Screening is recommended in symptomatic individuals and those considered to be at risk for iron overload based on medical history.
Hereditary hemochromatosis is defined as an inherited iron overload disorder characterized by excessive absorption of iron due to deficiency of hepcidin. Although it is seen worldwide, it is one of the most commonly identified genetic disorders in populations of northern European origin. Approximately 85% to 90% have a homozygous C282Y mutation in the HFE gene (Bacon, 2011). A smaller proportion (2% to 4%) have C282Y/H63D compound heterozygosity.
The measurement of liver iron concentration is regarded as the best predictor of total body iron, but the procedure is invasive and associated with risks. The two most useful serum measurements to evaluate iron overload are serum ferritin and TSAT, both of which are elevated in iron overload (Bacon, 2011). The measurement of TSAT is commonly used as an index of iron status. The test is especially useful in screening for hereditary hemochromatosis though not as useful in cases of overload caused by blood transfusions (Jensen, 2004). Serum ferritin has been shown to be a useful, non-invasive tool for monitoring iron status in situations of overload. However, serum ferritin is an acute phase reactant, increasing with inflammatory processes, infection, and chronic diseases. These etiologies should be investigated in individuals with elevated serum ferritin values suspected to have iron overload (Jensen, 2004). Serum ferritin levels have an additional value as a predictor of advanced fibrosis and cirrhosis in confirmed cases of hereditary hemochromatosis (Beaton, 2002; Guyader, 1998; Morrison, 2003).
Garcia-Casal and colleagues (2021) published a Cochrane Review evaluating the diagnostic accuracy of ferritin concentrations for detecting iron deficiency and the risk of iron overload in primary and secondary iron-loading syndromes. The review included 36 studies involving 1927 participants for iron overload. All studies concerned non-healthy populations, and none were specifically focused on infants, children, or individuals who are pregnant. The investigators found ferritin to have a specificity of 65% with a sensitivity of 80%. The estimated odds ratio was 8. The evidence indicates there is a low certainty that high concentrations of ferritin provide a sensitive test for iron overload in people where this condition is suspected.
The American College of Gastroenterology (ACG; Kowdley, 2019) issued guidelines on the management of hereditary hemochromatosis. The ACG recommends screening for hereditary hemochromatosis in individuals with family members, particularly first-degree relatives, diagnosed with hereditary hemochromatosis (conditional recommendation, very low quality of evidence). Screening in the general population is not recommended. Though not an official recommendation on iron studies related to the assessment of iron overload, the ACG guidelines include the following:
The initial approach to the evaluation of patients with suspected iron overload disorders includes measurement of serum iron level, TS [transferrin saturation], SF [serum ferritin], and unsaturated iron-binding capacity (UIBC). TS is the preferred initial screening test, and fasting is not required to accurately determine TS. A TS of greater than 45% identifies 97.9%–100% of C282Y homozygotes, although a small proportion of patients with HH [hereditary hemochromatosis] such as younger individuals at an earlier stage may have TS of < 45%. Iron overload may also be present with an elevated SF level and a normal TS level, particularly in non–HFE-related iron overload.
The British Society of Haematology (BSH) published guidelines on the investigation of raised serum ferritin (Cullis, 2018). Serum ferritin may be elevated in individuals with true iron overload, but it is recommended to investigate reactive causes of raised ferritin levels such as disease, malignancy, inflammatory, or metabolic disorders as they are more common (Grade 1B). In individuals with an incidental finding of elevated serum ferritin, a full blood count, a repeat serum ferritin, and TSAT should be included in the first line investigations (Grade 1C). In individuals with a moderately elevated serum ferritin level (<1000 µg/l) and normal TSAT, it may be reasonable to repeat assessment after 3 to 6 months (Grade 2C).
The American Association for the Study of Liver Diseases (AASDL; Bacon, 2011) published guidelines on the diagnosis and management of hereditary hemochromatosis. The AASDL recommends that individuals with abnormal iron studies should be evaluated as individuals with hemochromatosis, even in the absence of symptoms (Grade A). They also recommend evaluation for hemochromatosis in all individuals with evidence of liver disease (Grade 1B). Diagnostic evaluation using serum iron markers is recommended for high-risk individuals with a family history of hereditary hemochromatosis or suspected organ involvement (Grade 1B). In individuals with suggestive symptoms, physical findings, or family history of hereditary hemochromatosis, assessment should include a combination of TSAT and ferritin (Grade 1B). If TSAT is < 45% and ferritin is normal, no further evaluation is needed. In individuals with a TSAT ≥ 45% and/or elevated ferritin, further investigation is recommended. Screening by simultaneously performing iron studies and HFE mutation analysis in first-degree relatives of individuals with HFE-related hereditary hemochromatosis is recommended to detect early disease and prevent complications (Grade 1A). Individuals with hemochromatosis and iron overload are recommended to undergo therapeutic phlebotomy weekly, as tolerated (Grade 1A). Therapeutic phlebotomy is recommended in non-HFE iron overload in individuals with hepatic iron concentrations (Grade 1B). It is recommended that individuals with end-organ damage due to iron overload also undergo regular phlebotomy (Grade 1A). The target levels of phlebotomy for both groups of individuals should be a ferritin level of 50 to 100 µg/L (Grade 1B). The frequency of serum ferritin analysis varies by individual, but should be performed every 10 to 12 phlebotomies (approximately every 3 months) in the initial stages of treatment. As the target range of 50 to 100 µg/L is approached, testing may be repeated more frequently to avoid the development of overt iron deficiency. Frequency of phlebotomy varies by tolerance in each individual and frequency of serum ferritin analysis varies with it. General population screening in those with average risk for hereditary hemochromatosis is not recommended (Grade 1B).
The European Association for the Study of the Liver (EASL; 2010) published guidelines for HFE-associated hemochromatosis. The guidelines recommend that individuals with suspected iron overload have fasting measurements of TSAT and serum ferritin (Grade 1B). HFE testing (genetic testing) should be performed only on those with increased TSAT (Grade 1A). It is recommended that individuals from liver clinics are screened by measuring fasting TSAT and serum ferritin (Grade 1C) and offered HFE testing if TSAT is increased (Grade 1B). Diagnosis of HFE hemochromatosis requires evidence of increased iron stores and should not be based on C282Y homozygosity alone (Grade 1B). The EASL recommends treating individuals with HFE hemochromatosis and evidence of excess iron with phlebotomy (1C). The guidance indicates that data is lacking on an optimal treatment regimen and target serum iron indices. The goal of treatment is to prevent re-accumulation of iron once depletion has been achieved. Standard practice is to maintain serum ferritin between 50 to 100 µg/L which is typically achieved after 3 to 6 months of venesection. Some individuals may be offered ceasing of venesection with monitoring of serum ferritin then restarting a short program when serum ferritin reaches the upper limit of the normal range. Individuals with a C282Y homozygotic mutation and the absence of evidence for iron overload could be monitored annually and treatment instituted when serum ferritin rises above normal (Grade 2C).
References |
Peer Reviewed Publications:
Government Agency, Medical Society, and Other Authoritative Publications:
Websites for Additional Information |
Index |
Ferritin
Iron
TIBC
Total Iron Binding Capacity
Transferrin
The use of specific product names is illustrative only. It is not intended to be a recommendation of one product over another, and is not intended to represent a complete listing of all products available.
History |
Status | Date | Action |
Reviewed | 02/15/2024 | Medical Policy & Technology Assessment Committee (MPTAC) review. References section updated. Updated Coding section to consolidate diagnosis ranges, added ICD-10-CM codes D75.838-D75.839. |
| 09/27/2023 | Updated Coding section with 10/01/2023 ICD-10-CM changes; added N02.B9 to end of range. |
Reviewed | 02/16/2023 | MPTAC review. References section updated. Coding section updated with Z95.812 and removed Z95.818. |
| 04/21/2022 | Corrected typographical errors in diagnosis codes in the Coding section. |
New | 02/17/2022 | MPTAC review. Initial document development. |
Federal and State law, as well as contract language, and Coverage Guidelines take precedence over Clinical UM Guidelines. We reserve the right to review and update Clinical UM Guidelines periodically. Clinical guidelines approved by the Medical Policy & Technology Assessment Committee are available for general adoption by plans or lines of business for consistent review of the medical necessity of services related to the clinical guideline when the plan performs utilization review for the subject. Due to variances in utilization patterns, each plan may choose whether to adopt a particular Clinical UM Guideline. To determine if review is required for this Clinical UM Guideline, please contact the customer service number on the member's card.
Alternatively, commercial or FEP plans or lines of business which determine there is not a need to adopt the guideline to review services generally across all providers delivering services to Plan’s or line of business’s members may instead use the clinical guideline for provider education and/or to review the medical necessity of services for any provider who has been notified that his/her/its claims will be reviewed for medical necessity due to billing practices or claims that are not consistent with other providers, in terms of frequency or in some other manner.
No part of this publication may be reproduced, stored in a retrieval system or transmitted, in any form or by any means, electronic, mechanical, photocopying, or otherwise, without permission from the health plan.
© CPT Only – American Medical Association